Flap ventlid installing assembly, flap ventlid installing structure and installing method, and mold for molding a tire

ABSTRACT

A flap ventlid installing assembly comprising a flap ventlid and an anchor member, the top portion of which is connected to the flap ventlid and which has a longer portion not capable of being inserted as it is into the air removing hole through the opening and which has such a shape as capable of being press fitted into the air removing hole through the opening by making the longer portion to have such a size and shape capable of being inserted into the air removing hole with causing elastic deformation by applying an external force to the longer portion, and the flap ventlid can be installed in such a state that at least a part of the flap ventlid contacts with the design surface of the mold by press fitting the anchor member into the air removing hole, and the flap ventlid installing construction therefor.

BACKGROUND OF THE INVENTION

[0001] (1) Field of the Invention

[0002] The present invention relates to a flap ventlid installing assembly, a flap ventlid installing structure and a method for the installation, and a mold for molding a tire. More particularly, the present invention relates to a flap ventlid installing assembly according to which a flap ventlid which can prevent occurrence of spew (whisker projections) and burred extensions on a tire surface during tire molding and can retain the initial performance or external appearance of the tire obtained at satisfactory state can be simply installed in a mold for molding a tire, and besides clogging of ventholes of the mold due to penetration of rubber burrs can be easily avoided, an installing structure of the flap ventlid and a method for the installation, and a mold for molding a tire.

[0003] (2) Related Art Statement

[0004] The molds for molding a tire are often manufactured by means of casting which fits for the forming of complicated shapes conforming to the surface shape designed as complicated shapes having numerous thin projections termed sharp corners or blades for a tire.

[0005] Molds for molding a tire manufactured by means of this casting are ordinarily divided into sub-molds, and these sub-molds are combined to form a predetermined form as a whole at the time of forming a tire. There are as a method for dividing the mold a method of cutting into 7-11 sub-molds along the circumference (segmented mold type) and a method of cutting into 2 sub-molds in the direction of the central axis (one cast ring type), and these methods can be optionally selected depending on the production conditions, etc.

[0006] Molding of a tire using this type of the mold is ordinarily performed by a molding (compression molding) which comprises pressing to a mold a tire raw material (a green tire) comprising a polymerized rubber material before molding (before application of design).

[0007] In the course of such a compression molding, closed spaces (blockade spaces) are formed between the green tire and the mold surface on which projections and depressions such as ribs, blades, and the like are formed when a green tire is pressed into a mold. During molding, air within the blockade spaces is not discharged therefrom, and thus resultantly air bubbles are contained in the molded tire finally obtained. This is a problem that air bubble defects called “bear” are produced.

[0008] Further, after molding, molds for molding a tire should be ordinarily subjected to inspection and maintenance treatment inclusive of periodic cleanings and the like since the surface of the mold is roughened due to adherence of oils and fats and the like during repeated use. Depending on the mold, this cleaning and the like can become troublesome, requiring the introduction of long cleaning times and expensive equipment. This results in a problem that production costs of the articles produced increase.

[0009] To prevent the formation of the aforementioned “bear”, methods of removing air from molds are usually implemented to cope with this situation.

[0010] As a means for removing air from the closed spaces, there have been conventionally employed two types of means; one of which is called as a venthole type means and the other a non-spew or slit vent type means.

[0011] The method employing venthole type means is such a one that air within blockades is discharged therefrom to the outside through air removal apertures called a venthole installed in the mold so as to make them lead to blockades. In the case of this method, the manufacturing costs of the mold are less expensive, and, this method has an advantage since one may employ, for the maintenance and inspection, a simple blast method which comprises blowing media such as glass beads, resin beads, dry ice pellets, and the like to the interior surface of the mold with high-pressure air. However, spew (whisker projections) is formed on the final molded tire (the tire product) since air is discharged with accompanying the outflow of raw tire material (a green tire) into ventholes when the venthole type means is used. There is a disadvantage in that the external appearance and initial running performance of the molded tire are deteriorated.

[0012] The method employing a non-spew or slit vent type means is such a method that air within blockades is discharged to the outside through gaps formed between sub-molds or slit-like air removal means provided in the predetermined locations; thus this method is superior in the external appearance with respect to a molded tire. Further, there is an advantage in that there is not seen an adverse effect on the initial running performance. The occurrence of spew can be prevented when a non-spew or slit vent type means is employed, however, it cannot prevent the formation of burred extensions. Further, in the case of this type of a mold, not only the production cost of a mold is expensive, but also there is a disadvantage in that clogging during molding occurs readily. In addition to the above, with regard to maintenance and inspection, the mold should be broken down into every sub-mold, if one employs a simple blast method. Thus, it requires several man-hours for cleaning by blasting. Further, since slit portions clog readily with repeated blasting and the contaminants accumulated in slit portions are difficult to remove, special cleaning methods such as chemical cleaning and plasma cleaning should be used. This would require the cleaning for a long time and the introduction of expensive equipment. This is a disadvantage in that the production costs of the molded products increase.

[0013] As mentioned above, there are respective advantages and disadvantages in these two type means for air removal. Therefore, at present one should choose a proper mold, taking into consideration the use of tire to be produced, production costs, and the like. That is, at present, a mold equipped with a non-spew type means is used when a serious consideration must be given to the external appearance and the initial performance of a tire, with the acceptance of a relatively expensive production cost. On the other hand, however, a mold equipped with a venthole type means is used when a serious consideration must be given to the production cost of a mold and the running cost in tire molding, with the acceptance of a relatively poor external appearance and relatively poor initial running performance of a tire. Thus, a satisfactory measure in all aspects of the external appearance, the initial performance and the production costs of tire is sought after.

[0014] In light of these circumstances, various types of measures are being proposed. For example, there is proposed in JP-A-9-141660 a mold equipped with air removal lids provided in ventholes. This air removal lid is provided with a movable lid insert comprising an axis and a lid head disposed thereon. This lid head is provided with a cavity and a surface having a circular-truncated-cone-shape on the opposite side of the cavity, and being mostly flat on the side near to the cavity. Further, this air removal lid is provided with a casing and is press fitted into the venthole together with this casing.

[0015] An air removal lid thus configured has the functions mentioned below. Namely, the lid insert is always pressed to upper side by means of a spring loaded with force. Moreover, the lid insert is, during compression molding using a green tire, pressed down in opposition to the loaded force of a spring by means of pressing a level surface of the lid head into a green tire. During this downward pressing, air can be removed through gaps, that is, air passages, formed between the casing and lid insert. Further, infiltration into air passages of the green tire can be prevented by interrupting air passages with such contact of the casing and the circular-truncated-cone-shaped surface when compression molding is completed. Furthermore, the lid insert is pushed upwardly again by means of a loaded spring in the cavity during removal of the vulcanized tire from the mold after vulcanization is completed.

[0016] Nonetheless, a mold provided with said air removal lid suffers, as mentioned later, from clogging in a relatively high frequency due to constraints of that structure. The “leakage distance” which is an index for judging the easiness in clogging, defined as “Area in the Opening and Closing Surface of an Air Removal Lid, and possible defined also as the contact area between the casing and the circular-truncated-cone-shaped surface in the case of the device disclosed in JP-A-9-141660”, or, in other words, the “distance from the peripheral portion of the lid opening and closing surface to the holes for air removal” and the distance from the peripheral portion of the casing to the entrance of air passages in the case of the device disclosed in JP-A-9-141660 cannot be set to be long. In this event, rubber burrs are readily reachable up to the air removal holes, i.e., air passages during tire molding. As a consequence, there is such a problem that they infiltrate into air removal holes and cause clogging. Namely, said constraints are present as a result of the structure since the air removal lid must be embedded inside a tubular casing and stored. To avoid interference in designing, one can not employ a casing having an external diameter in terms of radius of approximately 3 mm or more. In this event, the internal diameter of the casing should be shortened to have a long leakage distance. The radius, however, must be approximately 1.6 mm even at a minimum since the air removal lid is housed in the venthole. Therefore, since there exists the boundary in having a long this leakage distance, clogging occurs readily from rubber burr infiltration into air removal holes (air passages). Thus, this brings a problem that the increase in the maintenance expenses (running cost) cannot be eliminated. Moreover, in the case that rubber burrs which have been temporarily infiltrated into the internal area of the air removal holes (air passages) are cut off at the time of demolding the tire from the mold, this would result in a further rise in the probability of the occurrence of clogging. This is because a portion corresponding to the leakage distance is housed in the internal portion of the air removal holes (air passages). Further, there is a problem in that production costs increase due to the numerous parts and complicated structures.

SUMMARY OF THE INVENTION

[0017] With respect to these problems, the inventors have proposed a flap ventlid which is provided on the tire mold surface side of the venthole and which has such a lid mechanism that in molding a tire by pressing a green tire to the respective surface of a tire mold, air is discharged from blockades with keeping an open state by spring up until said green tire contacts an upper portion of the mold and air is discharged from the blockades while reducing degree of its spring up during a period from a time when said green tire contacts said upper portion to a time when it reaches the surface of sub-molds, and simultaneously the green tire is prevented from flowing out by forming a closed state where the ventlids intimately contact with said green tire by dissolving its springing up when said green tire reaches the surfaces of said sub-molds (Japanese Patent Application No.2001-275807).

[0018] By installing a flap ventlid constructed as above in a tire molding mold, when molding a tire, the occurrence of spew (whisker projections) and burred extensions on a tire surface can be prevented and the tire obtained can have good initial performance and external appearance, and at the same time, the production costs of the tire molding mold per se can be reduced and clogging derived from rubber burr infiltration in ventholes can be effectively prevented and the running costs can be reduced by simplifying maintenance and inspection work.

[0019] The object of the present invention is to further improve the above-mentioned flap ventlid and to provide a flap ventlid installing assembly, an installing structure of the flap ventlid and an installation method, and a mold for molding a tire, according to which a flap ventlid which can prevent the occurrence of spew (whisker projections) and burred extensions on a tire surface during tire molding and can maintain the initial performance and external appearance of the resulting tire in satisfactory state can be simply installed in a tire molding mold, and, at the same time, clogging derived from rubber burr infiltration in air removing holes (ventholes) can be easily avoided.

[0020] For attaining the above object, the present invention provides the following flap ventlid installing assembly, installing structure of the flap ventlid and installation method, and mold for molding a tire.

[0021] [1] A flap ventlid installing assembly used for installing, at an opening of an air removing hole (venthole) on the design surface of a mold for molding a tire in which the air removing hole is formed, a flap ventlid which functions as an opening and closing lid passing or interrupting the flow of air at the opening, characterized in that the flap ventlid installing assembly comprises a flap ventlid and an anchor member, the top portion of which is connected to the flap ventlid and which has a longer portion which cannot be inserted as it is into the air removing hole through the opening and which has such a shape as capable of being press fitted into the air removing hole through the opening by making the longer portion to have such a size and shape capable of being inserted into the air removing hole with causing elastic deformation by applying an external force to the longer portion, and the flap ventlid can be installed in such a state that at least a part of the flap ventlid contacts with the design surface of the mold for molding a tire by press fitting (i.e., interference fitting) the anchor member into the air removing hole (hereinafter sometimes referred to as “the first invention”).

[0022] [2] A flap ventlid installing assembly used for installing, at an opening of an air removing hole (venthole) on the design surface of a mold for molding a tire in which the air removing hole (venthole) is formed, a flap ventlid which functions as an opening and closing lid passing or interrupting the flow of air at the opening, characterized in that the flap ventlid installing assembly comprises a flap ventlid and an anchor member, the top portion of which is connected to the flap ventlid and which has a length in longer direction longer than the depth of the air removing hole, and the flap ventlid can be installed in such a state that at least a part of the flap ventlid contacts with the design surface of the mold for molding a tire by inserting the anchor member into the air removing hole and bending the end portion of the anchor member projecting from the opening of the air removing hole on the side opposite to the design surface at the opening of the air removing hole on the side opposite to the design surface (hereinafter sometimes referred to as “the second invention”).

[0023] [3] A flap ventlid installing structure in which a flap ventlid which functions as an opening and closing lid passing or interrupting the flow of air at an opening of an air removing hole on the design surface of a mold for molding a tire in which an air removing hole is formed is provided at the opening of the air removing hole, characterized in that the flap ventlid installing assembly of the above [1] is installed in such a state that at least a part of the flap ventlid contacts with the design surface of the mold for molding a tire by press fitting the anchor member into the air removing hole (hereinafter sometimes referred to as “the third invention”).

[0024] [4] A flap ventlid installing structure in which a flap ventlid which functions as an opening and closing lid passing or interrupting the flow of air at an opening of an air removing hole on the design surface of a tire mold in which an air removing hole (venthole) is formed is provided at the opening of the air removing hole, characterized in that the flap ventlid installing assembly of the above [2] is installed in such a state that at least a part of the flap ventlid contacts with the design surface of the mold for molding a tire by inserting the anchor member into the air removing hole and bending the end portion of the anchor member projecting from the opening of the air removing hole on the side opposite to the design surface at the opening of the air removing hole on the side opposite to the design surface (hereinafter sometimes referred to as “the fourth invention”).

[0025] [5] A flap ventlid installing structure mentioned in the above [3] or[4], wherein the flap ventlid installing assembly is installed in such a state that when the flap ventlid installing assembly installed in the tire mold is drawn out from the air removing hole, the anchor member can rake out foreign matters accumulated in the air removing hole.

[0026] [6] A flap ventlid installing structure mentioned in the above [5], wherein the anchor member has a projection for raking out the foreign matters.

[0027] [7] A flap ventlid installing structure mentioned in the above [5] or [6], wherein the anchor member is made of a material to which the foreign matters accumulated in the air removing hole can readily adhere or such material is coated on the surface of the anchor member.

[0028] [8] A flap ventlid installing structure mentioned in any of the above [5] to [7], wherein the material is copper or a copper alloy.

[0029] [9] A method for installing at an opening of an air removing hole a flap ventlid which functions as an opening and closing lid passing or interrupting the flow of air at an opening of an air removing hole on the design surface of a mold for molding a tire in which the air removing hole is formed, characterized in that the anchor member is press fitted into the air removing hole using the flap ventlid installing assembly of the above [1] so that at least a part of the flap ventlid contacts with the design surface of the mold for molding a tire, thereby installing the flap ventlid (hereinafter sometimes referred to as “the fifth invention”).

[0030] [10] A method for installing at an opening of an air removing hole a flap ventlid which functions as an opening and closing lid passing or interrupting the flow of air at an opening of an air removing hole on the design surface of a mold for molding a tire in which the air removing hole is formed, characterized in that using the flap ventlid installing assembly of the above [2], the flap ventlid is installed in such a state that at least a part of the flap ventlid contacts with the design surface of the mold for molding a tire by inserting the anchor member into the air removing hole and bending the end portion of the anchor member projecting from the opening of the air removing hole on the side opposite to the design surface at the opening of the air removing hole on the side opposite to the design surface (hereinafter sometimes referred to as “the sixth invention”).

[0031] [11] A method for installing a flap ventlid mentioned in the above [9] or [10], wherein the flap ventlid installing assembly is installed in such a state that when the flap ventlid installing assembly installed in the tire mold is drawn out from the air removing hole, the anchor member can rake out foreign matters accumulated in the air removing hole.

[0032] [12] A method for installing a flap ventlid mentioned in the above [11], wherein the anchor member has a projection for raking out the foreign matters.

[0033] [13] A method for installing a flap ventlid mentioned in the above [11] or [12], wherein the anchor member is made of a material to which the foreign matters accumulated in the air removing hole can readily adhere or such material is coated on the surface of the anchor member.

[0034] [14] A method for installing a flap ventlid mentioned in any of the above [11] to [13], wherein the material is copper or a copper alloy.

[0035] [15] A mold for molding a tire which is provided with a flap ventlid installing structure mentioned in any of the above [3] to [8] (hereinafter sometimes referred to as “the seventh invention”).

BRIEF EXPLANATION OF DRAWINGS

[0036]FIG. 1 is an oblique view which schematically shows one embodiment of the flap ventlid installing assembly installed in a mold for molding a tire according to the present invention (the first invention).

[0037]FIG. 2(a) and FIG. 2(b) are oblique views which show steps in sequence in one embodiment of installing the flap ventlid installing assembly in a mold for molding a tire according to the present invention (the first invention).

[0038]FIG. 3(a) to FIG. 3(e) are oblique views which show steps in sequence in one embodiment of forming the flap ventlid installing assembly according to the present invention (the first invention).

[0039]FIG. 4(a) to FIG. 4(d) are oblique views which show steps in sequence in another embodiment of forming the flap ventlid installing assembly according to the present invention (the first invention).

[0040]FIG. 5(a) to FIG. 5(e) are explanatory drawings which schematically show another embodiment of the flap ventlid installing assembly installed in a mold for molding a tire according to the present invention (the first invention).

[0041]FIG. 6(a) and FIG. 6(b) are explanatory drawings which show steps in sequence in one embodiment of installing the flap ventlid installing assembly used for flap ventlid installing structure in a mold for molding a tire according to the present invention (the third invention).

[0042]FIG. 7(a) and FIG. 7(b) are explanatory drawings which show behavior in sequence of steps in one embodiment of drawing out the flap ventlid installing assembly used for flap ventlid installing structure from a mold for molding a tire, thereby raking out foreign matters accumulated in the venthole according to the present invention (the third invention).

[0043]FIG. 8(a) and FIG. 8(b) are explanatory drawings which schematically show another embodiment of the flap ventlid installing structure according to the present invention (the third invention).

[0044]FIG. 9 is an oblique view which shows another embodiment of the flap ventlid installing assembly according to the present invention (the third invention).

[0045]FIG. 10(a) and FIG. 10(b) are explanatory drawings which show steps in sequence in another embodiment of installing the flap ventlid installing assembly in a mold for molding a tire according to the present invention (the first invention).

[0046]FIG. 11 is an explanatory drawing which schematically shows one embodiment of the flap ventlid installing assembly installed in a mold for molding a tire according to the present invention (the first invention).

[0047]FIG. 12(a) and FIG. 12(b) are explanatory drawings which show behavior in sequence of steps in another embodiment of drawing out the flap ventlid installing assembly used for flap ventlid installing structure from a mold for molding a tire, thereby raking out foreign matters accumulated in the venthole according to the present invention (the third invention).

[0048]FIG. 13 is an oblique view which schematically shows one embodiment of the flap ventlid installing assembly installed in a mold for molding a tire according to the present invention (the second invention).

[0049]FIG. 14 is an oblique view which shows one embodiment of the flap ventlid installing assembly according to the present invention (the second invention).

[0050]FIG. 15(a) to FIG. 15(c) are oblique views which show steps in sequence in one embodiment of installing the flap ventlid installing assembly in a mold for molding a tire according to the present invention (the second invention).

[0051]FIG. 16(a) and FIG. 16(b) are explanatory drawings which show one embodiment of a mold for molding a tire used for flap ventlid installing structure according to the present invention (the fourth invention).

[0052]FIG. 17 is an explanatory drawing which shows one embodiment of a mold for molding a tire used for flap ventlid installing structure according to the present invention (the fourth invention).

[0053]FIG. 18 is an oblique view which schematically shows one embodiment of a mold for molding a tire and a flap ventlid installing assembly used for flap ventlid installing structure according to the present invention (the fourth invention).

[0054]FIG. 19(a) and FIG. 19(b) are explanatory drawings which schematically show a state in one embodiment of installing a flap ventlid installing assembly used for flap ventlid installing structure in a mold for molding a tire according to the present invention (the fourth invention).

[0055]FIG. 20 is an oblique view which schematically shows the behavior in one embodiment of drawing out the flap ventlid installing assembly used for flap ventlid installing structure from a mold for molding a tire, thereby raking out foreign matters accumulated in the venthole according to the present invention (the fourth invention).

[0056]FIG. 21 is an oblique view which schematically shows one embodiment of the flap ventlid installing assembly used for flap ventlid installing structure in which a projection is formed according to the present invention (the fourth invention).

[0057]FIG. 22 is an explanatory drawing which shows the mold for molding a tire used in all examples.

[0058]FIG. 23(a) to FIG. 23(d) are explanatory drawings which show the steps in sequence of forming the flap ventlid installing assembly used in Example 1.

[0059]FIG. 24(a) to FIG. 24(d) are explanatory drawings which show the steps in sequence of forming the flap ventlid installing assembly used in Example 2.

[0060]FIG. 25(a) to FIG. 25(d) are explanatory drawings which show the steps in sequence of forming the flap ventlid installing assembly used in Example 3.

[0061]FIG. 26(a) to FIG. 26(e) are explanatory drawings which show the steps in sequence of forming the flap ventlid installing assembly used in Example 4.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

[0062] Embodiments of a flap ventlid installing assembly, an installed structure of the flap ventlid and a method of installation, and a mold for molding a tire according to the present invention (the first invention to the seventh invention) will be specifically explained referring to the drawings.

[0063] First, the flap ventlid installing assembly which is one of the embodiments of the present invention (the first invention) will be explained. FIG. 1 shows a flap ventlid installing assembly which is used for installing, at an opening 5 of a venthole 4 on the design surface of a mold 3 for molding a tire (“a mold for molding a tire” is hereinafter sometimes referred to as “a tire mold” in which a venthole 4 is formed, a flap ventlid 1 which functions as an opening and closing lid passing or interrupting the flow of air at the opening 5. As shown in FIG. 2(a), the flap ventlid installing assembly 10 of the embodiment of the present invention is characterized in that it comprises a flap ventlid 1 and an anchor member 2, the top portion of which is connected to the flap ventlid 1 and which has a longer portion 6 which cannot be inserted as it is into the venthole 4 (see FIG. 1) through the opening 5 (see FIG. 1) of the tire mold 3 (see FIG. 1) and which has such a shape as capable of being press fitted into the venthole 4 through the opening 5 by making the longer portion 6 to have such a size and shape capable of being inserted into the venthole 4 with causing elastic deformation of the portion by applying an external force to the longer portion 6 as shown in FIG. 2(b), and the flap ventlid 1 can be installed in such a state that at least a part of the flap ventlid 1 contacts with the design surface of the tire mold 3 by press fitting the anchor member 2 into the venthole 4 as shown in FIG. 1.

[0064] By constructing in this way, in a tire mold 3 can be simply installed a flap ventlid 1 which can prevent occurrence of spew (whisker projections) and burred extensions on a tire surface during tire molding and can retain the initial performance or external appearance of the tire obtained in satisfactory state.

[0065] The flap ventlid installing assembly 10 of this embodiment can be formed, for example, in the following manner. First, an anchor material 7 is formed which has such a shape as shown in FIG. 3(a), for example, such a shape as the width of one end portion being narrower than the inner diameter of the venthole 4 (see FIG. 1) of the tire mold 3 (see FIG. 1) and the width of another end portion being wider than the inner diameter of the venthole 4 (see FIG. 1). Such anchor material 7 can be welded with the flap ventlid 1 (see FIG. 1) and can be formed by cutting out from a steel material having a suitable strength and spring characteristics. Although not particularly limited, there may be used, for example, spring steels, precipitation hardening stainless steels, precipitation hardening nickel alloys, etc. Furthermore, among these materials, precipitation hardening stainless steels and precipitation hardening nickel alloys which can maintain high strength characteristics for a long time in a temperature range of about 150-200° C. are suitable because the tire mold 3 (see FIG. 1) is kept and used for a long time in the above temperature range.

[0066] The thickness of the anchor material 7 varies depending on the diameter of the opening 5 (see FIG. 1) of the venthole 4 (see FIG. 1) into which the anchor member is press fitted, and, for example, in the case of the diameter of the opening 5 being about 0.8-1.6 mm, it is preferably about 0.05-0.40 mm. In this case, if the thickness of the anchor material 7 is less than 0.05 mm, sufficient self-pressing function cannot sometimes be developed when it is used for anchor member 2 (see FIG. 1), and if it is more than 0.40 mm, the opening 5 (see FIG. 1) of the venthole 4 is clogged with its thickness when it is used for anchor member 2 (see FIG. 1), and sufficient ventilation cannot sometimes be assured during molding of a tire.

[0067] Then, the resulting anchor material 7 is subjected to bending to form a shape as shown in FIG. 3(b), namely, to form an anchor member 2 which has a longer portion which cannot be inserted as it is into the venthole 4 (see FIG. 1) through the opening 5 (see FIG. 1) of the tire mold 3 (see FIG. 1) and which has such a shape as capable of being press fitted into the venthole 4 through the opening 5 by making the longer portion to have such a size and shape capable of being inserted into the venthole 4 with causing elastic deformation by applying an external force to the longer portion. The lower part 9 of the anchor member 2 subjected to bending develops a frictional force with inner wall surface of the ventihole 4 (see FIG. 1) when press fitted into the venthole 4 (see FIG. 1) and this is a part to be actually fixed in the tire mold 3 (see FIG. 1). Furthermore, the upper part 8 of the anchor member 2 is bent so that the flap ventlid 1 can be easily welded thereto. This flap ventlid 1 is preferably made of a flexible material which is chemically inert with a tire raw material before molding (green tire) and does not fusion bond thereto and which can be repeatedly used at a temperature of 100-200° C., and, for example, iron alloys (various steel materials) or nickel alloys can be exemplified. Furthermore, preferred are those which can be made thinner in their thickness to such an extent as the traces of the flap ventlid 1 causing no problems on the appearance of the tire.

[0068] Next, as shown in FIG. 3(c), the flap ventlid 1 is temporarily placed on the upper part 8 of the anchor member 2. It is preferred to bend the flap ventlid 1 in such a shape as effectively functioning as an opening and closing lid when installed in the tire mold 3 (see FIG. 1).

[0069] Next, as shown in FIG. 3(d), the flap ventlid 1 is welded to the upper part 8 of the anchor member 2 using a welding machine 11, etc. The welding of the flap vent lid 1 to the anchor member 2 may be carried out after installing the anchor member 2 in the tire mold 3 (see FIG. 1), but is preferably carried out before installation in the tire mold 3 (see FIG. 1) because positioning of the flap ventlid 1 and welding operation can be simply performed.

[0070] Next, as shown in FIG. 3(e), the shape of the anchor member 2 is adjusted so that it has a longer portion 6 which cannot be inserted as it is into the venthole 4 (see FIG. 1) through the opening 5 (see FIG. 1) of the tire mold 3 (see FIG. 1) and which has such a shape as capable of being inserted into the venthole 4 through the opening 5 by making to have such a size and shape capable of being inserted into the venthole 4 with causing elastic deformation by applying an external force thereto. Thus, a flap ventlid installing assembly 10 is formed.

[0071] Furthermore, as shown in FIG. 4(a), the anchor member 2 can also be formed using a spring pin 12 having a given outer diameter and a steel thin plate tab 13. As the spring pin 12, there may be suitably used commercially available spring pins (JIS B 2808), etc.

[0072] As shown in FIG. 4(b), the anchor member 2 is formed by integrating the spring pin 12 and the steel thin plate tab 13 by welding, etc., and as shown in FIG. 4(c) and FIG. 4(d), the flap ventlid 1 is welded to the resulting anchor member 2, whereby the flap ventlid installing assembly 10 can be formed.

[0073] Furthermore, for the formation of the flap ventlid installing assembly 10, the welding of the spring pin 12 to the steel thin plate tab 13 or the flap ventlid 1 to the anchor member 2 is preferably carried out by resistance welding (with very small current) such as percussion welding because trace of welding hardly remains and no welding fillers such as welding rod are needed in welding.

[0074] Usually, the inner diameter of the opening 5 of the venthole 4 formed in the tire mold 3 as shown in FIG. 1 is about 0.8-1.6 mm, and the outer diameter of the flap ventlid 1 of such a shape as hardly affecting the design surface of the tire mold 3 is about 2.5-4.0 mm. Therefore, the shape of the anchor member 2 used in this embodiment is not limited to one explained above, and can be any one having such a size as capable of welding with the flap ventlid 1 and imparting the function of self-bonding to the inner wall surface of the venthole 4.

[0075] Furthermore, the flap ventlid installing assembly of this embodiment may be such one in which the end portion opposite to the end portion to which the flap ventlid 1 is welded is bent so that the anchor member 2 cannot be inserted as it is into the venthole 4 and can be press fitted into the venthole 4 by elastic deformation with applying external force to the anchor member 2, or may be such one in which the anchor member 2 is bent at two or more portions. Furthermore, as shown in FIG. 5(c) and FIG. 5(d), the flap ventlid installing assembly of this embodiment may be such that two or more anchor members 2 are connected to one flap ventlid 1, and the end portion of at least one of the anchor members 2 may be bent. Moreover, as shown in FIG. 5(e), the flap ventlid installing assembly of this embodiment may be such that the anchor member 2 is bent at two or more portions. In the flap ventlid installing assemblies 10 shown in FIG. 5(a) to FIG. 5(e), the area including the bent portion of the anchor member 2 forms the longer portion in this embodiment, and the anchor member 2 is elastically deformed by applying an external force to the longer portion and press fitted into the venthole 4, and thus the flap ventlid installing assemblies 10 can be installed in the tire mold 3. By constructing as mentioned above, a simple structure is obtained, and, besides, press fitting into the venthole 4 is easily performed and falling of f at the time of molding can be effectively inhibited.

[0076] Next, the installation structure of the flap ventlid according to one embodiment of the present invention (the third invention) will be explained. As shown in FIG. 6(a) and FIG. 6(b), the installation structure 20 of the flap ventlid according to this embodiment is characterized in that the flap ventlid installing assembly 10 constructed in the same manner as the flap ventlid installing assembly 10 shown in FIG. 1 is installed in such a state that at least a part of the flap ventlid 1 contacts with the design surface of the tire mold 3 by press fitting the anchor member 2 into the venthole 4.

[0077] As mentioned before, the anchor member 2 of the flap ventlid installing assembly 10 has the longer portion 6 which cannot be inserted as it is into the venthole 4 and simultaneously has such a shape as capable of being press fitted into the venthole 4 from the opening 5 by making the longer portion 6 to have such a size and shape as capable of being inserted into the venthole 4 by causing elastic deformation with applying an external force to the longer portion 6. Therefore, in this embodiment, when the anchor member 2 is press fitted into the venthole 4, the length of the longer portion 6 reduces, and due to the restoring force of the reduced longer portion 6 per se, friction force with the inner wall surface of the venthole 4 increases, and thus the flap ventlid installing assembly 10 can be installed in the tire mold 3 in firmly fixed state.

[0078] By constructing in this way, in a tire mold 3 can be simply installed a flap ventlid 1 which can prevent occurrence of spew (whisker projections) and burred extensions on a tire surface during tire molding and can retain the initial performance or external appearance of the tire obtained in satisfactory state. Furthermore, the flap ventlid 1 can be simply installed in also a tire mold 3 made of an aluminum alloy or the like to which the flap ventlid cannot be directly welded. Moreover, since scaffold for welding to the tire mold 3 and caulking operation of the flap ventlid 1 per se are not required, breakage and the like of the surface of the tire mold having designs can be inhibited. Further, in this embodiment, the flap ventlid installing assembly 10 is removably provided, when the flat ventlid 1 must be changed owing to breakage or the like, it can be removed without leaving shape defects such as welding traces in the tire mold 3, and the flap ventlid installing assembly 10 can be simply installed only by inserting it in the tire mold 3.

[0079] Moreover, in this embodiment, it is preferred that as shown in FIG. 7(a) and FIG. 7(b), the flap ventlid installing structure 20 is provided in such a state that when the flap ventlid installing assembly 10 installed in the tire mold 3 is drawn out of the venthole 4, the anchor member 2 can rake out foreign matters 14 accumulated in the venthole 4. Specifically, suitable is a flap ventlid installing assembly 10 in which the flap ventlid 1 is welded to the anchor member 2 having a projection 15 for raking out the foreign matters 14 and which is installed in the tire mold 3.

[0080] When tires are repeatedly molded by the tire mold 3, foreign matters 14 such as rubber burrs are accumulated in the venthole 4, and sometimes cause clogging of the venthole. For example, when the flap vewntlid 1 is directly welded to the tire mold 3, the foreign matters 14 must be taken out after the flap ventlid 1 is peeled off from the tire mold 3, but in the flap ventlid installing structure 20 of this embodiment, the flap ventlid is removably installed in the tire mold 3 by press fitting the anchor member 2 into the tire mold 3, and the foreign matters 14 accumulated in the vethole 4 can be raked out by drawing out the anchor member 2 from the venthole 4. Therefore, the foreign matters 14 which cause clogging can be easily removed without leaving welding traces in the tire mold 3.

[0081] Moreover, in this embodiment, in place of forming the projection 15 mentioned above, the anchor member 2 may be made of a material to which the foreign matters 14 accumulated in the venthole 4 can readily adhere or such material may be coated on the surface, and as the material, there may be suitably used copper and copper alloys. By constructing in this way, the foreign matters 14 accumulated in the venthole 4 can readily be raked out only by drawing out the flap ventlid installing assembly 10 from the tire mold 3 without forming the anchor member 2 in a special shape. Thus, the foreign matters 14 accumulated in the venthole 4 can be raked out without forming the projection 15 or the like at the anchor member 2. Furthermore, the effect of raking out the foreign matters 14 can be further improved without forming the projection 15 or the like at the anchor member 2.

[0082] Hitherto, copper alloys have been considered unsuitable as materials of members constituting the tire mold 3 since they react with sulfur in the vulcanized rubber constituting the tire and hence are high in adhesion to the vulcanized rubber, but in this embodiment, the foreign matters 14 accumulated in the venthole 4 can be easily removed by adhering the foreign matters to the anchor member 2 with utilizing the characteristics of copper alloys mentioned above.

[0083] Especially, by using a beryllium-copper alloy as the material, in addition to the above effects, the stress of pressing the inner wall surface of the venthole 4 by the anchor member 2 press fitted into the venthole 4 can be maintained for a long time. This is because during being kept at about 200° C. which is the temperature of using the tire mold 3 for a long time, the beryllium-copper alloy has the aging induction deformation characteristics that the age (precipitation) hardening gradually proceeds and besides the alloy spontaneously deforms in the direction of initially imparted strain. The flap ventlid installing assembly 10 can be firmly installed in the tire mold 3 by forming the anchor member 2 in such a shape that the longer portion elastically shortened with proceeding of age-hardening reaction is age-induction deformed, and by utilizing effectively the age-induction deformation characteristics of the beryllium-coppoer alloy.

[0084] In the case of the anchor member 2 being formed of the above-mentioned metal or alloys comprising this metal, the material of the flap ventlid 1 must be formed of a material weldable to the anchor member 2. As mentioned above, the flap ventlid 1 can be made of spring steel, precipitation hardening type stainless steel, precipitation hardening type nickel alloy, or the like, but, for example, when the material of the anchor member 2 is a copper alloy, it is preferred to form the flap ventlid 1 using a nickel alloy since adhesion of various steel materials to a copper alloy by welding is low.

[0085] Further, in this embodiment, the flap ventlid installing assembly 10 as shown in FIG. 4(d) or the flap ventlid installing assemblies 10 as shown in FIG. 5(a) to FIG. 5(e) may be used for installation in the tire mold 3 (see FIG. 5(b)). In case the flap ventlid installing assemblies 10 as shown in FIG. 5(a) to FIG. 5(e) are used, the flap ventlid installing structure 20 may be such that a cylindrical falling-inhibition member 16 having a piercing hole smaller in inner diameter than the inner diameter of the venthole 4 is provided in the venthole 4 of the tire mold 3, and the anchor member 2 is press fitted into the piecing hole of the falling-inhibition member 16 as shown in FIG. 8(a) and FIG. 8(b). By constructing in this way, for example, in case the anchor member 2 falls off from the venthole 4 during the tire molding, the bent end portion of the anchor member 2 is stopped by the end face of the falling-inhibition member 16 opposite to the design surface side of the tire mold 3, whereby the flap ventlid installing assemblies 10 can be effectively inhibited from falling off.

[0086] Next, the flap ventlid installing assembly 10 of another embodiment of the present invention (the first invention) will be explained. As shown in FIG. 9, the flap ventlid installing assembly 10 of this embodiment comprises a flap ventlid 1 and an anchor member 2, the top portion of which is connected to the flap ventlid 1. The anchor member 2 used for the flap ventlid installing assembly 10 of this embodiment is in the form of a ring prepared by connecting both end portions of a strip-like thin plate.

[0087] As shown in FIG. 10(a), this ring-shaped anchor member 2 has a longer portion 6 which cannot be inserted as it is into the venthole 4 through the opening 5 of the tire mold 3 and besides has such a shape as capable of being press fitted into the venthole 4 through the opening 5 by making the longer portion 6 to have such a size and shape as capable of being inserted into the venthole 4 with causing elastic deformation by applying an external force to the longer portion 6 as shown in FIG. 10(b). Therefore, in the flap ventlid installing assembly 10 of this embodiment, the flap ventlid 1 can be installed in the state of at least a part of the flap ventlid 1 contacting with the design surface of the tire mold 3 by press fitting the anchor member 2 into the venthole 4.

[0088] By constructing in this way, in the tire mold 3 can be simply installed a flap ventlid 1 which can prevent occurrence of spew (whisker projections) and burred extensions on a tire surface during tire molding and can retain the initial performance or external appearance of the tire obtained at satisfactory state.

[0089] As materials used in this embodiment, there may be used the same materials as constituting the flap ventlid installing assembly 10 shown in FIG. 1.

[0090] Next, the installation structure of the flap ventlid according to another embodiment of the present invention (the third invention) will be explained. As shown in FIG. 11, the installation structure 20 of the flap ventlid according to this embodiment is characterized in that the flap ventlid installing assembly 10 constructed in the same manner as the flap ventlid installing assembly 10 provided with a ring-shaped anchor member 2 as shown in FIG. 9 is installed in the state of at least a part of the flap ventlid 1 contacting with the surface having design of the tire mold 3 by press fitting the anchor member 2 into the venthole 4.

[0091] By constructing in this way, in a tire mold 3 can be simply installed a flap ventlid 1 which can prevent occurrence of spew (whisker projections) and burred extensions on a tire surface during tire molding and can retain the initial performance or external appearance of the tire obtained in satisfactory state. Furthermore, the flap ventlid 1 can be simply installed in also a tire mold 3 made of an aluminum alloy or the like to which the flap ventlid 1 cannot be directly welded. Moreover, since scaffold for welding to the tire mold 3 and caulking operation of the flap ventlid 1 per se are not required, breakage and the like of the surface of the tire mold having designs can be inhibited. Further, in this embodiment, the flap ventlid installing assembly 10 is removably provided, when the flat ventlid 1 must be changed owing to breakage or the like, it can be removed without leaving shape defects such as welding traces in the tire mold 3, and a new flap ventlid installing assembly 10 can be simply installed only by inserting it in the tire mold 3.

[0092] Moreover, in this embodiment, it is preferred that as shown in FIG. 12(a) and FIG. 12(b), the flap ventlid installing assembly 10 is provided in such a state that when the flap ventlid installing assembly 10 installed in the tire mold 3 is drawn out from the venthole 4, the anchor member 2 can rake out the foreign matters 14 accumulated in the venthole 4. When the ring-shaped anchor member 2 used in this embodiment is installed by press fitting in the vethole 4, this is deformed to have an undercut shape, and by drawing out this deformed anchor member 2 from the venthole 4, the foreign matters 14 accumulated in the venthole 4 can simultaneously be raked out.

[0093] Moreover, in this embodiment, the anchor member 2 preferably has such construction that it is made of a material to which the foreign matters 14 accumulated in the venthole 4 can readily adhere or such material is coated on the surface, and, as the material, there may be suitably used copper and copper alloys.

[0094] Next, the flap ventlid installing assembly which is one of the embodiments of the present invention (the second invention) will be explained. FIG. 13 shows a flap ventlid installing assembly 30 which is used for installing a flap ventlid 31 which functions as an opening and closing lid passing or interrupting the flow of air at an opening 35, at the opening 35 of a venthole 34 on the design surface of a tire mold 3 in which a venthole 4 (air removing hole) is formed. As shown in FIG. 14, the flap ventlid installing assembly 30 of this embodiment is characterized in that it comprises a flap ventlid 31 and an anchor member 32, the top portion of which is connected to the flap ventlid 31 and which has a length in longer direction longer than the depth of the venthole 34 (see FIG. 13), and the flap ventlid 31 can be installed in the state of at least a part of the flap ventlid 31 contacting with the design surface of the tire mold 33 as shown in FIG. 15(c) by inserting the anchor member 32 of the flap ventlid installing assembly 30 from the opening 35 of the venthole 34 at the design surface as shown in FIG. 15(a) and bending the end portion of the anchor member 32 projecting from an opening 36 of the venthole 34 on the side opposite to the design surface at the opening 36 of the venthole 34 on the side opposite to the design surface as shown in FIG. 15(b).

[0095] By constructing as above, in the tire mold 33 can be simply installed the flap ventlid 31 which can prevent occurrence of spew (whisker projections) and burred extensions on a tire surface during tire molding and can retain the initial performance or external appearance of the tire obtained at satisfactory state.

[0096] In general, as for the tire mold 33, it is used in such a manner as the design surface 41 of the tire mold 33 being held by a back mold 42 as shown in FIG. 16(a) and FIG. 16(b). FIG. 16(a) shows a tire mold of 2P mold type (one cast ring type) and FIG. 16(b) shows a tire mold of sectional mold type (segmented mold type). In this tire mold 33, only by piercing a venthole (not shown) from the design surface 41 of the tire mold 33 to the back surface, sufficient ventilation cannot be assured because the opening of the venthole (not shown) is closed by the back mold 42 which surface-contacts with the back surface side. Therefore, as shown in FIG. 17, ordinarily, an air escaping groove portion 45 connected directly to the venthole 34 is formed on the back surface side (outer peripheral surface) of the design surface 41 of the tire mold 33. In FIG. 16(a) and FIG. 16(b), the reference numeral 43 indicates a side wall and 44 indicates a bead ring.

[0097] According to this embodiment, the anchor member 32 (see FIG. 13) is fixed utilizing the air escaping groove 45 formed on the back surface side of the design surface 41 of the tire mold 33.

[0098] As shown in FIG. 18, the flap ventlid 31 and the anchor member 32 used in this embodiment can be formed of the same materials as of the flap ventlid 1 and the anchor member 2 shown in FIG. 1. Furthermore, the anchor member 32 can be formed by using a plate-like anchor material longer than the length L of the venthole 34 of the tire mold 33 and by subjecting this anchor material to bending so that the flap ventlid 31 can be welded to the anchor material. This anchor material is preferably formed so that it is longer than the length L of the venthole 34 by the length of the portion to which the flap ventlid 31 is welded and the length of the portion bent at the opening 36 of the venthole 34 on the side opposite to the designed surface. The flap ventlid installing assembly 30 can be formed by welding the flap ventlid 31 to the portion of the anchor member 32 which is subjected to bending. The welding of the flap ventlid 31 and the anchor member 32 can be performed by the same method as shown in FIG. 3(d) using a welding machine.

[0099] The flap ventlid installing assembly 30 formed in the above manner is inferior to the flap ventlid installing assembly 10 shown in FIG. 1 in maintenance and workability because the body of tire mold 33 (mold for design surface) must be removed from the back mold 42 (see FIG. 16(a)) at the time of changing of the flap ventlid installing assembly 30, but the flap ventlid installing assembly 30 has the advantages that the possibility of the flap ventlid installing assembly 30 falling off from the tire mold 33 during removal of the molded tire can be considerably reduced, and stability of tire molding can be improved.

[0100] Furthermore, in this embodiment, since the shape of the anchor member 32 is simple, production cost can be reduced. Moreover, according to this embodiment, the initial installing operation into the tire mold 33 is very easy, and the changing of the flap ventlid installing assembly 30 can be performed very easily except for the operation of removing the mold in which the design surface 41 (see FIG. 16(a)) is formed from the back mold 42 (see FIG. 16(a)).

[0101] Next, the flap ventlid installing assembly which is one of the embodiments of the present invention (the fourth invention) will be explained. As shown in FIG. 19(a), the flap ventlid installing structure 50 of this embodiment is characterized in that as shown in FIG. 19(a), the flap ventlid installing assembly 30 constructed in the same manner as the flap ventlid installing assembly 30 shown in FIG. 14 is installed in such a state that at least a part of the flap ventlid 31 contacts with the design surface of the tire mold 33 by inserting the anchor member 32 from the opening 35 of the venthole 34 at the design surface and bending the end portion of the anchor member 32 projecting from the opening 36 of the venthole 34 on the side opposite to the design surface at the opening 36 of the venthole 34 on the side opposite to the design surface.

[0102] In this embodiment, the end portion of the anchor member 32 projecting from the opening 36 of the venthole 34 on the side opposite to the design surface is bent at the opening 36 on the side opposite to the design surface utilizing the air escaping groove 45 formed on the back surface side of the design surface of the tire mold 33 (see FIG. 17). In FIG. 19(a), the end portion of the anchor member 32 is bent in the same direction as the opening direction of the flap ventlid 31 which functions as an opening and closing lid, but may be bent in the direction opposite to the opening direction of the flap ventlid 31 as shown in FIG. 19(b). Since the flap ventlid installing structure 50 shown in FIG. 19(b) is constructed in the same manner as the flap ventlid installing structure 50 shown in FIG. 19(a), the same reference numerals are given to the same elements with omitting the explanations thereof.

[0103] As shown in FIG. 19(a) and FIG. 19(b), according to the flap ventlid installing structure 50 of this embodiment, in a tire mold 33 can be simply installed the flap ventlid 31 which can prevent occurrence of spew (whisker projections) and burred extensions on a tire surface during tire molding and can retain the initial performance or external appearance of the tire obtained in satisfactory state. Furthermore, the flap ventlid 31 can be simply installed in also the tire mold 33 made of an aluminum alloy or the like to which the flap ventlid 31 cannot be directly welded. Moreover, since scaffold for welding to the tire mold 33 and caulking operation of the flap ventlid 31 per se are not required, breakage and the like of the design surface of the tire mold 33 can be avoided. Further, in this embodiment, the flap ventlid installing assembly 30 is removably provided, when the flat ventlid 31 must be changed owing to breakage or the like, it can be removed without leaving shape defects such as welding traces in the tire mold 33, and a new flap ventlid installing assembly 30 can be simply installed only by inserting it in the tire mold 33.

[0104] Moreover, in this embodiment, it is preferred that as shown in FIG. 20, the flap ventlid installing assembly 30 is provided in such a state that when the flap ventlid installing assembly 30 installed in the tire mold 33 is drawn out from the venthole 34, the anchor member 32 can rake out the foreign matters 46 accumulated in the venthole 34. Specifically, suitable is a flap ventlid installing assembly 30 in which the flap ventlid 31 is welded to the anchor member 32 having projections 47 for raking out the foreign matters 46 (see FIG. 20) and which is installed in the tire mold 33 (see FIG. 20).

[0105] Moreover, in this embodiment, the anchor member 32 preferably has such construction that it is made of a material to which the foreign matters 46 accumulated in the venthole 34 can readily adhere or such material is coated on the surface as shown in FIG. 20, and, as the material, there may be suitably used copper and copper alloys. By constructing in this way, the foreign matters 46 accumulated in the venthole 34 can readily be raked out only by drawing out the flap ventlid installing assembly 30 from the tire mold 33 without forming the anchor member 32 in a special shape. Thus, the foreign matters 46 accumulated in the venthole 34 can be raked out without forming the projections 47 (see FIG. 21) or the like at the anchor member 32. Furthermore, the effect of raking out the foreign matters 46 can be further improved without forming the projections 47 (see FIG. 21) or the like at the anchor member 32.

[0106] Hitherto, copper alloys have been considered unsuitable as materials of members constituting the tire mold 33 since they react with sulfur in the vulcanized rubber constituting the tire and hence are high in adhesion to the vulcanized rubber of tire, but in this embodiment, the foreign matters 46 accumulated in the venthole 34 can be easily removed by adhering the foreign matters to the anchor member 32 with utilizing the characteristics of copper alloys mentioned above.

[0107] In the case of the anchor member 32 being formed of the above-mentioned metal or alloys comprising the metal, the material of the flap ventlid 31 must be formed of a material weldable with the anchor member 32. The flap ventlid 31 can be made of spring steel, precipitation hardening type stainless steel, precipitation hardening type nickel alloy, or the like, but, for example, when the material of the anchor member 32 is a copper alloy, it is preferred to form the flap ventlid 31 using a nickel alloy because of low adhesion of various steel materials to a copper alloy by welding.

[0108] Next, the method for installing a flap ventlid according to the present invention (the fifth invention) will be explained. As shown in FIG. 6(a) and FIG. 6(b), the method is for installing, at the opening 5 of a venthole 4 on the design surface of the tire mold 3 in which the venthole 4 is formed, the flap ventlid 1 which functions as an opening and closing lid passing or interrupting the flow of air at the opening 5, characterized in that the anchor member 2 is press fitted into the venthole 4 using the flap ventlid installing assembly 10 of the first invention shown in FIG. 1 so that at least a part of the flap ventlid 1 contacts with the design surface of the tire mold 3, thereby installing the flap ventlid.

[0109] By constructing as above, in the tire mold 3 can be simply installed the flap ventlid 1 which can prevent occurrence of spew (whisker projections) and burred extensions on a tire surface during tire molding and can retain the initial performance or external appearance of the tire obtained at satisfactory state.

[0110] Furthermore, the flap ventlid installing assembly 10 used in this embodiment is not limited to the flap ventlid installing assembly 10 shown in FIG. 1, but may be of any shapes so long as the flap ventlid installing assembly 10 comprises the flap ventlid 1 and the anchor member 2, the top portion of which is connected to the flap ventlid 1 and which has the longer portion 6 which cannot be inserted as it is into the venthole 4 from the opening 5 of the tire mold 3, and which has such a shape as capable of being press fitted into the venthole 4 from the opening 5 by making the longer portion 6 to have such a size and shape capable of being inserted into the venthole 4 with causing elastic deformation by applying an external force to the longer portion 6, and, for example, the flap ventlid installing assembly 10 as shown in FIG. 9 may be used.

[0111] Moreover, in the method for installing the flap ventlid of this embodiment, as shown in FIG. 7(a) and FIG. 7(b), it is preferred that the flap ventlid installing assembly 10 is installed in such a state that when the flap ventlid installing assembly 10 installed in the tire mold 3 is drawn out from the venthole 4, the anchor member 2 can rake out foreign matters 14 accumulated in the venthole 4. Specifically, suitable is a method which comprises carrying out installation in the tire mold 3 using the flap ventlid installing assembly 10 in which the projection 15 for raking out the foreign matters 14 is provided at the anchor member 2.

[0112] Moreover, in this embodiment, it is preferred to use the flap ventlid installing assembly 10 in which the anchor member 2 has such construction that it is made of a material to which the foreign matters 14 accumulated in the venthole 4 readily adheres or such material is coated on the surface, and, as the material, there may be suitably used copper and copper alloys. By constructing in this way, the foreign matters 14 accumulated in the venthole 4 can readily be raked out only by drawing out the flap ventlid installing assembly 10 from the tire mold 3 without forming the anchor member 2 in a special shape.

[0113] Next, the method for installing a flap ventlid according to the present invention (the sixth invention) will be explained. As shown in FIG. 13, the method is for installing, at the opening 35 of the venthole 34 on the design surface of the tire mold 33 in which the venthole 34 is formed, the flap ventlid 31 which functions as an opening and closing lid passing or interrupting the flow of air at the opening 35, characterized in that the flap ventlid 31 is installed in the tire mold 33 as shown in FIG. 15(c) by using the flap ventlid installing assembly 30 as shown in FIG. 14, and inserting the anchor member 32 in the venthole 34 so that at least a part of the flap ventlid 31 contacts with the design surface of the tire mold 33 as shown in FIG. 15(a), and bending the end portion of the anchor member 32 projecting from the opening 36 of the venthole 34 on the side opposite to the design surface at the opening 36 of the venthole 34 on the side opposite to the design surface as shown in FIG. 15(b).

[0114] By constructing as above, in the tire mold 33 can be simply installed the flap ventlid 31 which can prevent occurrence of spew (whisker projections) and burred extensions on the tire surface during tire molding and can retain the initial performance or external appearance of the tire obtained at satisfactory state.

[0115] Furthermore, the flap ventlid installing assembly 30 used in this embodiment is not limited to the flap ventlid installing assembly 30 shown in FIG. 14, but may be of any shapes so long as the flap ventlid installing assembly 30 comprises the flap ventlid 31 and the anchor member 32, the top portion of which is connected to the flap ventlid 31 and which has a length in the longer direction longer than the depth of the venthole 34, and the flap ventlid 31 can be installed in the state of at least a part of the flap ventlid 31 contacting with the design surface of the tire mold 33 by bending the end portion of the anchor member 32 projecting from the opening 36 of the venthole 34 on the side opposite to the design surface at the opening 36 of the venthole 34 on the side opposite to the design surface.

[0116] In this embodiment, as shown in FIG. 20, it is preferred that the flap ventlid installing assembly 30 is installed in such a state that when the flap ventlid installing assembly 30 installed in the tire mold 33 is drawn out from the venthole 34, the anchor member 32 can rake out the foreign matters 46 accumulated in the venthole 34. Specifically, suitable is a method which comprises carrying out installation in the tire mold 33 using the flap ventlid installing assembly 30 in which the projections 47 (see FIG. 21) for raking out the foreign matters 46 are provided at the anchor member 32.

[0117] Moreover, in this embodiment, it is preferred to use the flap ventlid installing assembly 30 in which the anchor member 32 has such construction that it is made of a material to which the foreign matters 46 accumulated in the venthole 34 readily adheres or such material is coated on the surface, and, as the material, there may be suitably used copper and copper alloys. By constructing in this way, the foreign matters 46 accumulated in the venthole 34 can readily be raked out only by drawing out the flap ventlid installing assembly 30 from the tire mold 33 without forming the anchor member 32 in a special shape.

[0118] Next, the mold for molding a tire which is one embodiment of the present invention (the seventh invention) will be explained. The mold has the flap ventlid installing structure 20 of the third invention as shown in FIG. 6(b). By constructing in this way, the flap ventlid 31 which can prevent occurrence of spew (whisker projections) and burred extensions on a tire surface during tire molding and can retain the initial performance or external appearance of the tire obtained at satisfactory state can be easily exchanged during molding of tires.

[0119] The flap ventlid installing structure 20 used in this embodiment is not limited to the flap ventlid installing structure 20 shown in FIG. 6(b), and it may be of any shapes so long as it is the flap ventlid installing structure of the present invention (the third invention and the fourth invention).

[0120] The flap ventlid installing assembly, the flap ventlid installing structure and the installing method, and the tire mold explained above are not limited to those mentioned above and may be of any shapes so long as the flap ventlid can be installed in the tire mold with the above-mentioned construction. For example, a wire can be used as the anchor member in place of the plates. Furthermore, the method for bonding the anchor member and the flap ventlid is not limited to welding.

EXAMPLES

[0121] The present invention will be explained in more specifically by the following examples, which should not be construed as limiting the invention in any manner. In all of the examples, a tire mold 53 of sectional mold type (segmented mold type) made of AC4C aluminum alloy (7% Si, 0.4% Mg, 1% Cu, 0.5% Fe with the remainder being Al) as shown in FIG. 22. This tire mold 53 had a shape of 320 mm in overall height, φ600 mm in inner diameter, φ700 mm in outer diameter and 50 mm in wall thickness, and had about 1000 ventholes 54 of φ1.2 mm in opening diameter of opening 55 which were formed in the design surface part. This tire mold 53 was made by a plaster casting method.

Example 1

[0122] In Example 1, an anchor material 57 having the shape as shown in FIG. 23(a) was formed using a solution heat treated material (SUS 631), heated at 1000° C. for 1 hour and then quenched.

[0123] Then, the anchor material 57 was bent in such a shape as shown in FIG. 23(b) and then subjected to age-hardening heat treatment for forming martensite to form an anchor member 52. The age-hardening heat treatment for forming martensite was performed by heating at 760° C. for 90 minutes, then subjecting to air cooling, further heating at 560° C. for 60 minutes, and then subjecting to air cooling.

[0124] Then, a flap ventlid 51 having the shape as shown in FIG. 23(c) was formed. The flap ventlid 51 was formed of the same material as of the anchor member 52 (FIG. 23(b)) and subjected to the same age-hardening treatment.

[0125] Then, the anchor member 52 and the flap ventlid 51 were bonded by percussion welding to form a flap ventlid installing assembly 60 as shown in FIG. 23(d). The conditions of the welding were as follows: An electrode made of pure copper and having a welding electrode diameter of φ0.8 mm was used and the welding power was 15 W sec.

[0126] The thus formed flap ventlid installing assembly 60 was installed in the tire mold 53 (see FIG. 22) by press fitting the assembly into the venthole 54 (see FIG. 22) to form a tire mold of this example.

[0127] As a result of continuously molding 20000 tires using the tire mold of this example, good results were obtained without causing bare defects of tires and spew at the positions corresponding to the ventholes. Furthermore, there occurred no defects such as falling off of the flap ventlid installing assembly from the tire mold.

Example 2

[0128] In Example 2, an anchor material 67 as shown in FIG. 24(a) was formed, and an anchor member 62 having projections as shown in FIG. 24(b) was formed. Furthermore, as shown in FIG. 24(c), a flap ventlid 61 having an outer diameter of φ2.0 mm was welded as shown in FIG. 24(d) to form a flap ventlid installing assembly 70. The anchor member 62 and flap ventlid 61 were formed of the same material as in Example 1, and the same age-hardening heat treatment was conducted. This flap ventlid installing assembly 70 was installed in the tire mold 53 (see FIG. 22) by press fitting the assembly into the venthole 54 (see FIG. 22) to form a tire mold of this example.

[0129] As a result of continuously molding 3000 tires using the tire mold of this example, clogging occurred in the ventholes 54 (see FIG. 22) in which the flap ventlid installing assemblies 70 were installed. When the flap ventlid installing assemblies 70 were drawn out from the ventholes 54 (see FIG. 22), nearly all clogging materials could be removed in each of the flap ventlid installing assemblies 70.

Example 3

[0130] In Example 3, an anchor material 77 having the shape as shown in FIG. 25(a) was formed using a solution heat treated material (BeA25), and this was heated at 800° C. for 1 hour and then quenched.

[0131] Then, the anchor material 77 was bent in such a shape as shown in FIG. 25(b) and then subjected to age-hardening heat treatment to form an anchor member 72. The age-hardening heat treatment was performed by heating at 320° C. for 2 hours and then subjecting to air cooling.

[0132] Then, a flap ventlid 71 having the shape as shown in FIG. 25(c) was formed. The flap ventlid 71 was formed using Inconel 718, and this was subjected to heat treatment at 955° C. for 1 hour, then air cooling, bending, heating at 720° C. for 8 hours, cooling in a furnace, further heating at 620° C. for 8 hours, and then air cooling.

[0133] Then, the anchor member 72 and the flap ventlid 71 were bonded by percussion welding to form a flap ventlid installing assembly 80 as shown in FIG. 25(d). The conditions of the welding were as follows: An electrode made of pure copper and having a welding electrode diameter of φ0.8 mm was used and the welding power was 20 W sec.

[0134] The thus formed flap ventlid installing assembly 80 was installed in the tire mold 53 (see FIG. 22) by press fitting the assembly into the venthole 54 (see FIG. 22) to form a tire mold of this example.

[0135] As a result of continuously molding 3000 tires using the tire mold of this example, clogging occurred in the ventholes 54 (see FIG. 22) in which the flap ventlid installing assemblies 80 were installed. When the flap ventlid installing assemblies 80 were drawn out from the ventholes 54 (see FIG. 22), nearly all clogging materials could be removed in each of the flap ventlid installing assemblies 80.

Example 4

[0136] In Example 4, an anchor material 87 having the shape as shown in FIG. 26(a) was formed using a solution heat treated material (BeA25), heated at 800° C. for 1 hour and then quenched.

[0137] Then, one end portion of the anchor material 87 was crushed in the form of a plane by pincers and the like as shown in FIG. 26(b) and then subjected to age-hardening heat treatment (heating at 280° C. for 2 hours and then air cooling) as shown in FIG. 26(c).

[0138] Then, a flap ventlid 81 having the shape as shown in FIG. 25(d) was formed. The flap ventlid 81 was formed using Inconel 718, which was subjected to heating at 955° C. for 1 hour, then air cooling, bending, heating at 720° C. for 8 hours, cooling in a furnace, further heating at 620° C. for 8 hours, and then air cooling.

[0139] Then, the anchor member 82 and the flap ventlid 81 were bonded by percussion welding to form a flap ventlid installing assembly 90 as shown in FIG. 26(e). The conditions of the welding were as follows: An electrode made of pure copper and having a welding electrode diameter of φ0.8 mm was used and the welding power was 20 W sec.

[0140] When the thus formed flap ventlid installing assembly 90 was installed in a tire mold in which the ventholes were clogged, the top portion of the anchor member 82 pushed out the foreign matters which caused the clogging to solve the clogging of the ventholes. The end portion projecting from the opening of the venthole on the side opposite to the design surface was bent at the opening to form the tire mold of this example.

[0141] As a result of continuously molding 20000 tires using the tire mold of this example, good results were obtained without causing bare defects of tires and without forming spew at the positions corresponding to the ventholes. Furthermore, there occurred no defects such as falling off of the flap ventlid installing assembly from the tire mold.

[0142] As explained above, according to the present invention, the flap ventlid which can prevent occurrence of spew (whisker projections) and burred extensions on a tire surface during tire molding and can retain the initial performance or external appearance of the tire obtained at satisfactory state can be simply installed in a mold for molding a tire, and besides the clogging caused by penetration of rubber burrs etc. into the air removing holes (ventholes) of the mold for molding tires can be easily solved. 

What is claimed is:
 1. A flap ventlid installing assembly used for installing, at an opening of an air removing hole (venthole) on a design surface of a mold for molding a tire in which the air removing hole is formed, a flap ventlid which functions as an opening and closing lid passing or interrupting the flow of air at the opening, characterized in that the flap ventlid installing assembly comprises a flap ventlid and an anchor member, the top portion of which is connected to the flap ventlid and which has a longer portion not capable of being inserted as it is into the air removing hole through the opening and which has such a shape as capable of being press fitted into the air removing hole through the opening by making the longer portion to have such a size and shape capable of being inserted into the air removing hole due to elastic deformation caused by applying an external force to the longer portion, and the flap ventlid can be installed in such a state that at least a part of the flap ventlid contacts with the design surface of the mold for molding a tire by press fitting the anchor member into the air removing hole.
 2. A flap ventlid installing assembly used for installing, at an opening of an air removing hole (venthole) on a design surface of a mold for molding a tire in which the air removing hole is formed, a flap ventlid which functions as an opening and closing lid passing or interrupting the flow of air at the opening, characterized in that the flap ventlid installing assembly comprises a flap ventlid and an anchor member, the top portion of which is connected to the flap ventlid and which has a length in longer direction longer than the depth of the air removing hole, and the flap ventlid can be installed in such a state that at least a part of the flap ventlid contacts with the design surface of the mold for molding a tire by inserting the anchor member into the air removing hole and bending the end portion of the anchor member projecting from the opening of the air removing hole on the side opposite to the design surface at the opening of the air removing hole on the side opposite to the design surface.
 3. A flap ventlid installing structure where a flap ventlid which functions as an opening and closing lid passing or interrupting the flow of air at an opening of an air removing hole on a design surface of a mold for molding a tire in which the air removing hole is formed is installed at the opening of the air removing hole, characterized in that the flap ventlid installing assembly of claim 1 is installed in such a state that at least a part of the flap ventlid contacts with the design surface of the mold for molding a tire by press fitting the anchor member into the air removing hole.
 4. A flap ventlid installing structure where a flap ventlid which functions as an opening and closing lid passing or interrupting the flow of air at an opening of an air removing hole on a design surface of a mold for molding a tire in which the air removing hole (venthole) is formed is installed at the opening of the air removing hole, characterized in that the flap ventlid installing assembly of claim 2 is installed in such a state that at least a part of the flap ventlid contacts with the design surface of the mold for molding a tire inserting the anchor member into the air removing hole and bending the end portion of the anchor member projecting from the opening of the air removing hole on the side opposite to the design surface at the opening of the air removing hole on the side opposite to the design surface.
 5. A flap ventlid installing structure according to claim 3, wherein the flap ventlid installing assembly is installed in such a state that when the flap ventlid installing assembly installed in the mold for molding a tire is drawn out from the air removing hole, the anchor member can rake out foreign matters accumulated in the air removing hole.
 6. A flap ventlid installing structure according to claim 5, wherein the anchor member has a projection for raking out the foreign matters.
 7. A flap ventlid installing structure according to claim 5, wherein the anchor member is made of a material to which the foreign matters accumulated in the air removing hole can readily adhere or such material is coated on the surface of the anchor member.
 8. A flap ventlid installing structure according to claim 5, wherein the material is copper or a copper alloy.
 9. A method for installing at an opening of an air removing hole (venthole) a flap ventlid which functions as an opening and closing lid passing or interrupting the flow of air at the opening of the air removing hole on a design surface of a mold for molding a tire in which the air removing hole is formed, characterized in that the anchor member is press fitted into the air removing hole using the flap ventlid installing assembly of claim 1 so that at least a part of the flap ventlid contacts with the design surface of the mold for molding a tire, thereby installing the flap ventlid at the opening of the air removing hole.
 10. A method for installing at an opening of an air removing hole (venthole) a flap ventlid which functions as an opening and closing lid passing or interrupting the flow of air at the opening of the air removing hole on a design surface of a mold for molding a tire in which the air removing hole is formed, characterized in that using the flap ventlid installing assembly of claim 2, the flap ventlid is installed in such a state that at least a part of the flap ventlid contacts with the design surface of the mold for molding a tire by inserting the anchor member into the air removing hole and bending the end portion of the anchor member projecting from the opening of the air removing hole on the side opposite to the design surface at the opening of the air removing hole on the side opposite to the design surface.
 11. A method for installing a flap ventlid according to claim 9, wherein the flap ventlid installing assembly is installed in such a state that when the flap ventlid installing assembly installed in the mold for molding a tire is drawn out from the air removing hole, the anchor member can rake out foreign matters accumulated in the air removing hole.
 12. A method for installing a flap ventlid according to claim 11, wherein the anchor member has a projection for raking out the foreign matters.
 13. A method for installing a flap ventlid according to claim 11, wherein the anchor member is made of a material to which the foreign matters accumulated in the air removing hole readily adheres or such material is coated on the surface of the anchor member.
 14. A method for installing a flap ventlid according to claim 11, wherein the material is copper or a copper alloy.
 15. A mold for molding a tire which is provided with a flap ventlid installing structure according to claim
 3. 